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NTIS 바로가기한국구조물진단유지관리공학회 논문집 = Journal of the Korea Institute for Structural Maintenance and Inspection, v.26 no.5, 2022년, pp.95 - 102
차수원 (울산대학교 토목공학과) , 최영철 (가천대학교 토목환경공학과)
Recently, there has been a growing interest in reducing greenhouse gases in all industrial fields. In the construction industry, studies have been conducted for the use of high-volume fly ash concrete to replace cement with fly ash. Quantitative measurements of cement hydration and fly ash reactivit...
Liu, J., Qiu, Q. W., Chen, X. C., Wang, X. D., Xing, F., Han, N. X., He,Y. J. (2016) , Degradation of fly ash concrete under the coupled effect of carbonation and chloride aerosol ingress, Corrosion Science, 112, 364-372.
Liu, J., Qiu, Q. W., Xing, F., Pan, D. (2014) , Permeation properties and pore structure of surface layer of fly ash concrete, Materials, 7(6), 4282-4296.
Jin, Z. Q., Sun, W., Zhang, Y. S., Jiang, J. Y., Lai, J. Z. (2007), Interaction between sulfate and chloride solution attack of concretes with and without fly ash, Cement and Concrete Research, 37(8), 1223-1232.
Metha, P. K. (2004), High-performance, high-volume fly ash concrete for sustainable development, Proceedings of the International Workshop on Sustainable Development and Concrete Technology, Beijing, 3-14.
Berry, E. E., Hemmings, R. T., Zhang, M. H., Cornelious, B. J., Golden, D. M. (1994), Hydration in high-volume fly ash binders, ACI Mater J, 91(4), 382-389.
Moon, G. D., Oh, S., Choi, Y. C. (2016), Effects of the physicochemical properties of fly ash on the compressive strength of high-volume fly ash mortar, Construction and Building Materials, 124, 1072-1080.
Lam, L,. Wong, Y. L., Poon, C. S. (2000), Degree of hydration and gel/space ratio of high volume fly ash/cement systems, Cement and Concrete Research, 30(5), 747-756.
Berrey, E. E., Hemmings, R. T., Cornelius, B. J. (1990), Mechanisms of hydration reaction in high volume fly ash cements and mortars, Cement and Concrete Composites, 12(4), 253-261.
Zeng, Q., Li, K., Fen-Chong, T., Dangla, P. (2012), Pore structure characterization of cement pastes blended with high volume fly-ash, Cement and Concrete Composites, 42(1), 194-204.
Zhao, H., Qin, X., Liu, J., Zhou, L., Tian, Q., Wang, P. (2018), Pore structure characterization of early-age cement pastes blended with high-volume fly ash, Construction and Building Materials, 189, 934-946.
De Weerdt, K., Ben Haha, M,. Le Saout, G., Kjellsen, K. O., Justnes, H., Lothenbach, B. (2011), Hydration mechanisms of ternary Portland cements containing limestone powder and fly ash, Cement and Concrete Research, 41(3), 279-291.
Baert, G., Hoste, S., De Schutter, G., De Belie, N. (2008), Reactivity of fly ash in cement paste studied by means of thermogravimetry and isothermal calorimetry, Journal of Thermal Analysis and Calorimetry, 94(2), 485-492.
Lothenbach, B., Scrivener, K., Hooton, R. D. (2011), Supplementary cementitious materials, Cement and Concrete Research, 41(12), 1244-1256.
Yilmaz, B., Olgun, A. (2008), Studies on cement and mortar containing low-calcium fly ash, limestone, and dolomitic limestone, Cement and Concrete Composites, 30(3), 194-201.
Luke, K., Glasser, F. P. (1988), Internal chemical evolution of the constitution of blended cements, Cement and Concrete Research, 18(4), 495-502.
Ohsawa, S., Asaga, K., Goto, S., Daimon, M. (1985), Quantitative determination of fly ash in the hydrated fly ash-CaSO4ㆍ2H2O-Ca(OH)2 system, Cement and Concrete Research, 15, 357-366.
Li, S., Roy, D. M., Kumer, A. (1985), Quantitative determination of pozzolanas in hydrated system of cement or Ca(OH)2 with fly ash or silica fume, Cement and Concrete Research, 15(6), 1079-1086.
Gopalan, M. K. (1993), Nucleation and pozzolanic factors in strength development of Class F fly ash concrete, ACI Materials Journal, 90(2), 117-121.
Feldman, R. F., Carette, G. G., Malhotra, V. M. (1990), Studies on of development of physical and mechanical properties of high-volume fly ash-cement pastes, Cement and Concrete Composites, 12(4), 245-251.
Marsh, B. K., Day, R. L., Bonner, D. G. (1985), Pore structure characteristics affecting the permeability of cement paste containing fly ash, Cement and Concrete Research, 15(6), 1027-1038.
Hinrichs, W., Odler, I. (1989), Investigation of the hydration of portland blastfurnace slag cement hydration kinetics, Advances in Cement Research, 2(5), 9-13.
Papadakis, V. G. (1999), Effect of fly ash on Portland cement systems Part I. Low-calcium fly ash, Cement and Concrete Research, 29(11) , 1727-1736.
Zeng, Q., Li, K., Fen-Chong, T., Dangla, P. (2010), Surface fractal analysis of pore structure of high-volume fly-ash cement pastes, Applied Surface Science, 257(3), 762-768.
Zhao, H., Qin, X., Liu, J., Zhou, L., Tiane, Q., Wang, P. (2018), Pore structure characterization of early-age cement pastes blended with high-volume fly ash, Construction and Building Materials, 189, 934-946.
Yu, Ye, G. (2013), The pore structure of cement paste blended with fly ash, Construction and Building Materials, 45(7), 30-35.
Taylor, H. F. W. (1997), Cement Chemistry, second ed. Thomas Telford, London.
Bhatty, J. I. (1986), Hydration versus strength in a portland cement developed from domestic mineral wastes-A comparative study, Thermochimica Acta, 106, 93-103.
Bhatty, J. I., Reid K. J. (1985), Use of thermal analysis in the hydration studies of a type 1 portland cement produced from mineral tailings, Thermochimica Acta, 91, 95-105.
Escalante-Garcia, J. I.. (2003), Nonevaporable water from neat OPC and replacement materials in composite cements hydrated at different temperatures, Cement Concrete Research, 33(11), 1883-1888.
Bentz, D. P., Sato, T., De la Varga, I., Weiss, W. J. (2012), Fine limestone additions to regulate setting in high volume fly ash mixtures, Cement & Concrete Composites, 34, 11-17.
Poon, C. S., Lam, L., Wong, Y. L. (2000), A study on high strength concrete prepared with large volumes of low calcium fly ash, Cement Concrete Research, 30, 447-455.
Chindaprasirt, P., Jaturapitakkul, C., Sinsiri, T. (2007), Effect of fly ash fineness on microstructure of blended cement paste, Construction and Building Materials, 21(7), 1534-1541.
Fraay, A. L. A., Bijen, J. M., Dehaan,Y. M. (1989), The reaction of fly ash in concrete - a critical examination, Cement and Concrete. Research, 19(2), 235-246.
Rahhal, V., Talero, R. (2004), Influence of two different fly ashes on the hydration of Portland cements, Journal of Thermal Analysis and Calorimetry, 78(1), 191-205.
Barbhuiya, S. A. Gbagbo, J. K., Russell, M. I., Basheerm, P. A. M. (2009), Properties of fly ash concrete modified with hydrated lime and silica fume, Construction and Building Materials, 23(10), 3233-3239.
Nayak, D. K., Abhilash, P. P., Singh, R., Kumar, R., Kumar, V. (2022), Fly ash for sustainable construction: A review of fly ash concrete and its beneficial use case studies, Cleaner Materials, 6, 100143.
Mocharla, I.R., Selvam, R., Govindaraj, V., Muthu, M. (2022), Performance and life-cycle assessment of high-volume fly ash concrete mixes containing steel slag sand, Construction and Building Materials, 341, 127814.
Wang, T., Ishida, T., Gu, R., Luan, Y. (2021), Experimental investigation of pozzolanic reaction and curing temperature-dependence of low-calcium fly ash in cement system and Ca-Si-Al element distribution of fly ash-blended cement paste, Construction and Building Materials, 267, 121012.
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